4/7/2016. Basic 12-Lead EKG Interpretation OBJECTIVES. Objectives Continued. Ryan Pratt MSN

Basic 12-Lead EKG Interpretation Ryan Pratt MSN OBJECTIVES Upon the successful completion of this course, the participant will be able to: Relate the significance of the anatomy and physiology of the heart to the identification and management of myocardial infarction Identify the components of a cardiac waveform and the correlation to cardiac activity Demonstrate measurement of waveform duration Identify different types of waveform morphology and Identify the components of a 12 lead EKG and discuss the advantages over a traditional 3 lead Discuss critical concepts in ACS Identify the differences between a diagnostic and monitoring 12 lead Objectives Continued Recognize the presence and significance of the following conditions upon obtaining and interpreting the 12 lead EKG: - Myocardial Infarction - Bundle branch blocks - Axis deviation 12 Lead EKG Mimics Identify the common mimics and describe their prevalence. Describe process and interpretation techniques for managing mimics. 12 Lead EJG Case Study 1

Critical Concepts in ACS ST elevation - the key to the acute reperfusion therapy subset You can t confirm ST elevation without a 12-lead ECG Perform on every patient suspected of ACS Obtain early Repeat frequently Background and Prevalence The Center for Disease control reported in its national vital statistics report that in 2011 there were 2,512,873 deaths in the United States. Of those 778, 503 were from major cardiovascular diseases. (Hoyert & Xu, 2012) That means 32% of the deaths that occurred in 2011 were from a heart diseases related event. The American College of Cardiology Foundation/American Heart Association (ACCF/AHA) 2013 Guideline for the Management of ST-Elevation Myocardial Infarction states, At present, STEMI comprises approximately 25% to 40% of MI presentations (O gara et al., 2013, p. 6). Etiology Cardiac cells can only survive about 20 minutes without oxygen before they are completely dead. However EKG changes will occur within 30-60 seconds of hypoxia. After a few seconds all of the oxygen reserves in the myocardial cells are used up. The cardiac cells then turn to glycogen stores and anaerobic metabolism. (McCance, Huether, Brashers, & Rote, 2010), 2

Etiology Risk factors that increase the risk of an acute myocardial infarction: - Age: anyone over 55 years old - Tobacco use - Diabetes - Hypertension - Hyperlipedemia - Family history of AMI - Obesity - Stress - Illegal drug use. Retrieved from: http://www.mayoclinic.com/health/heartattack/ds00094/dsection=risk-factors Anatomy and physiology Chambers Atria Ventricles Valves Tricuspid Pulmonary Mitral Aortic Septum (McCance, Huether, Brashers, & Rote, 2010), picture retrieved from texasheartinstitute.org Anatomy and Physiology - Epicardium Very thin outer layer Blood supply to the heart begins in this layer. -Myocardium Middle layer, majority of the blood supply for the heart is in this layer. - Endocardium The inner layer, has the least circulation because the vessels are smaller and fewer as they branch inward. (McCance, Huether, Brashers, & Rote, 2010), picture retrieved from texasheartinstitute.org 3

Anatomy and Physiology RCA Right ventricle Inferior wall of LV Posterior wall of LV (75%) SA Node (60%) AV Node (>80%) LCA Septal wall of LV Anterior wall of LV Lateral wall of LV Posterior wall of LV (10%) (McCance, Huether, Brashers, & Rote, 2010), picture retrieved from texasheartinstitute.org Laboratory and Diagnostic tests Laboratory - Myoglobin: onset as early as 1-2 hours, peaks in 4-8 hours. Low specificity! Best to r/o AMI. Normal 0 to 85 ng/ml. - Troponin I: onset in 2-4 hours, peaks in 10-24 hours. Not affected by cardio version. Also a clinical indicator of reperfusion. Normal <0.4 ng/ml. - CK-MB: onset in 3-4 hours, peaks in 10-24 hours. Normal 0-3 ng/ml - Troponin is by far the most cardiac specific enzyme, Cardiac troponin is the preferred biomarker and is more sensitive than creatine kinase isoenzyme (CK- MB). Cardiac troponins are useful in diagnosis, risk stratification, and determination of prognosis. An elevated level of troponin correlates with an increased risk of death, and greater elevations predict greater risk of adverse outcome. (O Conner et al., 2010, p. S791). Laboratory and Diagnostic tests Diagnostic - Diagnostic cardiac catherization. - 12- Lead EKG The gold standard in AMI diagnosis is to perform a 12-lead EKG. A 12-Lead EKG allows for the following: Rapid Identification of Infarction/Injury diagnosis made sooner in many cases Decreased Time to Reperfusion Treatment speeds preparation of & time to reperfusion therapies Modification to Therapies 4

Conduction Basics HEART ANATOMY Conduction System Sinus Node Bachmann s Bundle Internodal Pathways AV Junction AV node Bundle of His Ventricular System Bundle Branches Purkinje Fibers EKG Leads EKG leads detect depolarization and repolarization as they spread through the atria and the ventricles. The flat line on an EKG read out is called the isoelectric line. All EKG leads are set up so that a depolarizing current moving towards it will produce a deflection on the ECG paper above the isoelectric line. This is also known as a positive deflection. A depolarizing current moving away from a lead produces a deflection below the isoelectric line. This is also known as a negative deflection. For repolarization the exact opposite occurs. 5

BASIC EKG REVIEW Waveform Measurement The P Wave The P wave is the first wave of the cardiac cycle. It denotes the depolarization of the right and left artia. Also known as the firing of the SA node with the resulting contraction of the atria. So the P wave represents Atrial Systole. The P wave should be smooth and rounded. The PR interval should be less than.20 seconds. This is measured from the start of the P wave to the start of the QRS. 6

The QRS complex The QRS complex represents ventricular depolarization and contraction. Also known as ventricular systole. The Q wave is the first negative (or downward) deflection following the P wave. It represents depolarization of the interventricular septum. The R and S wave represent depolarization of the right and left ventricles. The beginning of the QRS is measured from the point where the first wave of the complex begins to deviate from baseline. The end of the QRS is marked at the point in which the last wave of the complex begins to level out at the isoelectric line. This is also called the J point. The normal QRS interval is less than.12 seconds. During the QRS complex atrial repolarization occurs but the atrial activity is hidden by the QRS complex. The T Wave and ST segment The T wave represents ventricular repolarization. The ST segment is the portion between the QRS complex (J Point) and the T wave. The ST segment should be even with the isoelectric line or elevated 1mm (one small box). A deviation is bad and usually indicates infarct/ischemia. 7

The Basics of 12-Lead EKG principles How to Obtain a 12-Lead EKG V1: fourth intercostal space to right of sternum V2: fourth intercostal space to left of sternum V3: directly between leads V2 and V4 V4: fifth intercostal space at left midclavicular line V5: level with V4 at left anterior axillary line V6: level with V5 at left midaxillary line 8

Chest Lead Placement Why does placement matter? As little as 2cm off can give false readings. ST depression ST elevation Normal EKG What do these leads represent? 9

Lead Views EKG Leads Limb Leads Limb Leads 10

EKG Leads Augmented Limb Leads Augmented Leads EKG Leads Precordial Leads 11

Precordial Leads Monitoring vs Diagnostic ECGs Monitoring Quality ECG Designed to provide information needed to determine rate and underlying rhythm Designed to filter out artifact Reduces the amount and degree of electrical activity seen by the ECG monitor Monitoring vs Diagnostic ECGs Diagnostic Quality ECG Designed to accurately reproduce QRS, ST and T waveforms Designed to look more broadly at the cardiac electrical activity Unfortunately, may result in greater artifact being visible 12

Monitoring vs Diagnostic ECGs Frequency Response Term used to describe the breadth of the electrical spectrum viewed by the ECG monitor Diagnostic quality is usually 0.05 Hz to 150 Hz Monitor quality is usually 0.5 Hz to 20-50 Hz Usually printed on the ECG recording strip Monitoring vs Diagnostic ECGs ECG Accuracy Calibration Voltage measured vertically Each 1 mm box = 0.1 mv 1 mv = 10 mm calibration standard Confirm calibration calibration impulse should be 10 mm (2 big boxes tall) stated calibration should be x 1.0 13

Calibration Calibration ECG Accuracy Paper Speed Standard is 25 mm/sec Faster paper speed means the rhythm will appear slower and the QRS wider Slower paper speed means the rhythm will appear faster and the QRS narrower Paper Speed Paper Speed 14

How to Obtain a 12-Lead Check for calibration and paper speed. Calibration should be 10 mm (2 big boxes) and stated x1.0; and the paper speed should be 25 mm/sec. Calibration Paper Speed 12-lead ECG 12-Lead ECG 080.0 0.080 80 milliseconds = 0.08 seconds 15

ECG Accuracy Look for: Negative avr if avr upright, look for reversed leads One complete cardiac cycle in each lead Diagnostic frequency response Proper calibration Appropriate speed EVOLVING PATTERN OF MYOCARDIAL INFARCTION Tall T wave ST segment T wave Pathologic Q wave EKG normalizes, Q wave remains as evidence of MI EKG changes must be present in two or more anatomically contiguous leads to be indicative of MI! Infarction: Necrosis; Q waves on ECG Injury: Cells cannot fully recover; ST elevation on ECG Ischemia: Viable cells; T wave inversion on ECG Pathophysiology of AMI Zones of Infarction, Injury, and Ischemia ( Bulls-Eye inner to outer circle) 16

Waveform Components: Practice Find J-points and ST segments How to Read a 12-Lead EKG Lead Views 17

I See All Leads How to read a 12-Lead EKG This is a normal 12-Lead. No ST-elevation V5, V6, here. I, and avl represent the V3 and V4 Everything comes Lateral back wall. Specifically V5 and V1 and V6 V2 represent the to the isotonic Low line. lateral. I and avl High the lateral. septum. anterior wall. This is were we are looking II, III, and avf for ST-elevation. At the J- represent inferior point. leads. Some 12 leads will have a running lead at the bottom. 18

How to read a 12-Lead EKG To make it easy on yourself remember this saying: I See All Leads. I = Inferior, S = Septal, A = anterior, and L = lateral Leads See All I Leads Inferior wall II-III-AVF RCA Septal wallv1-v2 LAD Anterior wall V3-V4 LAD Lateral wall I-AVL- V5-V6 LCX How to read a 12-Lead EKG Continuous Leads 1 1 4 1 2 2 5 2 3 3 6 19

How to read a 12-Lead EKG Practice It is important to note that EKG changes must be present in two or more anatomically contiguous leads to be indicative of MI! V4, V5, and V6 we so no ST segment changes. Here we see ST-Depression also known as reciprocal changes. We are not as worried with them as we are the ST-Elevation s!! Can you see the elevation? Infarction: Necrosis; Q waves on ECG Injury: Cells cannot fully recover; ST elevation on ECG Ischemia: Viable cells; T wave inversion on ECG Pathophysiology of AMI Zones of Infarction, Injury, and Ischemia ( Bulls-Eye inner to outer circle) 20

What does that 12-lead mean to us? First and foremost this patient is having an active myocardial infarction and needs to get to a cardiac cath lab. But we also now know a lot more thanks to the 12-Lead. Lets review our anatomy. -We know the inferior wall is being affected. -We also know that the inferior wall is supplied by the RCA. -So we now know that we have an occlusion in our RCA. -Since the RCA also supplies the right ventricle, we want to be very cautious with nitroglycerin administration in an inferior wall MI. This is because the right ventricle and right side of the heart is pre-load dependent. Since nitroglycerin is a potent vasodilator it will cause sever hypotension if given in an inferior wall MI. Inferior Wall (McCance, Huether, Brashers, & Rote, 2010) Right Side ECG 12 LEAD EKG INTERPRETATION 21

SO? One more practice. Did you see all of this elevation? Did this throw you off? Remember there needs to be elevation in two anatomical continuous leads! But we see not elevation here. So no lateral wall involvement. What does that 12-lead show us? This patient is obviously having an AMI. And this 12-lead shows us it is a very bad one and we need to hurry! But why? -We know we have an Anteroseptal Infarct with lateral extension. -That tells us that the infarct is occluding both the LAD and the circumflex, so the occlusion is likely in the LCA. -Knowing our anatomy that means the whole left side of the heart is ischemic and is not receiving oxygenated blood. -These patients are often called widow makers because they never make it to Lateral the hospital. Septal -If you see this 12-lead this patient needs a cath lab as soon as possible!! Anterior (McCance, Huether, Brashers, & Rote, 2010) Infarct Localization 22

Posterior View of the Heart Circumflex artery (from left coronary artery) Lateral wall Inferior wall Leads II, III, avf Posterior wall Right coronary artery Posterior descending artery NOTE 1: Inferior wall supplied by either the right (85% to 90% of people) or left coronary artery. NOTE 2: If there is acute injury in inferior leads (II, III, avf), unknown whether left or right coronary artery is blocked. NOTE 3: KEY you must obtain a RIGHT- SIDED ECG at once. Extent of Infarct Cardiac Anatomy in Relation to the Coronary Arteries Right coronary artery Septal wall V 1 -V 2 Anterior wall V 3 -V 4 Left main coronary artery Circumfle x artery Left anterior descending artery Lateral wall I, avl, V 5 - V 6 23

Extent of Infarct Inferior Lateral Infarction 24

Posterior View of the Heart Circumflex artery (from left coronary artery) Lateral wall Inferior wall Leads II, III, avf Posterior wall Right coronary artery Posterior descending artery NOTE 1: Inferior wall supplied by either the right (85% to 90% of people) or left coronary artery. NOTE 2: If there is acute injury in inferior leads (II, III, avf), unknown whether left or right coronary artery is blocked. NOTE 3: KEY you must obtain a RIGHT- SIDED ECG at once. Extent of Infarct 12 LEAD EKG INTERPRETATION Acute Reciprocal Changes 25

12 LEAD EKG INTERPRETATION Acute Reciprocal Changes So, what do you see here? 26

How about here? And here? 27

Bundle Branch Blocks Objectives Identify criteria for determining Left and Right Bundle Branch Blocks Identify criteria for determining Axis deviation Discuss implications for patients with BBB or Axis deviation Why do we care? Delay in conduction through either right or left bundle branches Causes ventricular activation and depolarization to occur more slowly Delays in conduction exacerbate CHF and acute infarctions Knowing this can effect your plan of care 28

Right BBB Late depolarization of the right ventricle. QRS is widened greater than 0.12 Complex will appear mainly positive with R wave appearing late Viewed best in lead V1 Possible causes include CAD, heart defects, acute heart failure, MI, drug effects or electrolyte imbalances Significance of RBBB May be an aid in diagnosing certain conditions May occur in normal hearts RBBB 29

Left BBB Blockage of the left BB disrupts normal left to right ventricular activation Depolarizing impulse travels from right to left through interventricular septum QRS widened greater than 0.12 Significance of LBBB LBBB has a more serious prognosis than RBBB because of its close correlation with organic heart disease Indicates underlying CAD, valvular disease, HTN or MI Does not occur in healthy people LBBB 30

RBBB vs LBBB 31

RECOGNITION OF AXIS DEVIATION Axis Deviation Shifting of the hearts electric axis beyond the normal range of 0 to 90 degrees Develops when an abnormality of the heart occurs such as hypertrophy, MI, LBBB, WPW, cardiomyopathy May develop in non cardiac conditions such as emphysema, ascites, abdominal tumors, pregnancy and PE Left Axis Deviation May occur in Anterior Lateral MI s WPW Hyperkalemia Emphysema Blocks Hypertrophy 32

Right Axis Deviation May occur with Inferior MI s RBBB Right Ventricular hypertrophy PE Right axis deviation is a normal finding in children Extreme Axis Deviation Caused by a more severe presentation of typical causes As an example a small inferior MI would produce right axis deviation, while a massive inferior MI would shift axis even further to produce extreme right axis deviation Another Method Axis Lead I Lead II Lead III avf Comments Normal 0 to 90 Positive Positive Positive Positive Physiologic Left 0 to -40 Positive Positive or split Negative Negative Pathologic Left -40 to 90 Right 90-180 Extreme right Positive Negative Negative Negative Anterior hemiblock Negative Positive, split or negative Positive Positive Posterior hemiblock Negative Negative Negative Negative Ventricular origin 33

What kind of block is it? Imposters Pericarditis Represents 5% of the patients that are seen in the hospital each year for chest pain. Causes include: Viral, bacterial, parasites, fungal, neoplastic, immune disorders, trauma, and idiopathic. Pericarditis should be identified by a sound assessment before it is noted on the 12-Lead. 34

Pericarditis Signs and Symptoms The classic sign of pericarditis is a pericardial friction rub that is heard over the left lower sternal border. Sharp, severe retrosternal chest pain that is worse in the supine position and with inspiration. Fever, chills, tachycardia. These patients will often present like an AMI patient. Pain is not relieved by NTG. EKG changes in Pericarditis Diffuse ST Segment elevation in all leads except AVR. ST Segment will have a concave appearance. PR Depression will be present in the acute phase. Pericarditis 12-Lead Diffuse ST-Segment Elevation PR Depression Concave ST-Segment Elevation 35

Pericarditis 12-Lead Pericarditis Treatment In most patients treatment is supportive and with NSAIDS. If the underlying cause has been identified and is not viral, a specific treatment regimen can be ordered. Left Ventricular hypertrophy (LVH) Increase in mass of the left ventricle. Can be a common finding in patients with hypertension. Diagnosed by 12-Lead EKG or echocardiography. Sensitivity of ECG to diagnose LVH is 7 to 35 percent in mild LVH and only 10 to 50 percent with moderate to severe disease. A patient with LVH has a 40% increased risk for a major myocardial event. 36

Sokolow-Lyon indices Sum of S wave in V1 and R wave in V5 or V6 3.5 mv (35 mm) and/or R wave in avl 1.1 mv (11 mm) Sokolow-Lyon indices 17 + 29 = 46 Cornell voltage criteria This criteria is based off of EKG studies that are designed to detect LVH in patients. The only gender specific criteria. For men: S in V3 plus R in avl >2.8 mv (28 mm) For women: S in V3 + R in avl >2.0 mv (20 mm) 37

Cornell Voltage Criteria for 56 yo male 16 15 16 + 15 = 31 Romhilt-Estes Point Score System This system is a points based system for specific EKG findings. A score of 5 of more is indicative of LVH. A score of 4 is a probable finding for LVH. Romhilt-Estes Point Score System 38

Left Ventricular hypertrophy (LVH) Treatment Treating the patients hypertension will decrease the cardiac mass through: Antihypertensive agents Weight loss Sodium restrictions Hyperkalemia High potassium levels in the body can be caused by inadequate excretion (urinary), or excessive release of potassium from the cells. Clinical manifestations of hyperkalemia occur when serum potassium levels reach 7.0 meq/l in chronic patients or possibly at lower levels with an acute rise in serum potassium. Hyperkalemia Clinical Manifestations Muscle weakness and paralysis: Ascending in nature usually starting at the feet and progressing to the trunk and arms. Respiratory weakness is rare. Cardiac Abnormalities/Arrhythmias: RBB, LBB, Sinus Bradycardia, Sinus Arrest, Ventricular Tachycardia, Ventricular Fibrillation, and Asystole. 39

Hyperkalemia Clinical Manifestations 12-lead EKG Changes Include: Tall peaked T waves. Shortened QT interval. As serum potassium levels rise to dangerous levels the PR interval will lengthen, QRS will widen, and the P wave may disappear. Hyperkalemia on a 12-lead Hyperkalemia 40

Case Study A 47 Y/O male with no prior history of CAD developed onset of Left-sided chest pain intermittently over the last 2 months. It occurred with exertion and at rest with some bilateral hand tingling and arm pain. No nausea or vomiting, or shortness of breath. Symptoms lasted several minutes, and then self-resolved. Case Scenario His symptoms worsened over the last 3 nights occurring at rest. 3 days ago he called his local EMS and had an ECG and blood pressure checked. His BP was slightly elevated and his ECG was found to be WNL. He waited until the next day to call his PCP. He was seen 2 days later. Case Scenario His PCP repeated his EKG, which was normal, and started him on HCTZ and Nexium. That evening, he developed 7/10 chest pain with bilateral hand tingling and pain. He called 911 and was taken to his local ED. His ECG was repeated and looked like this 41

Case Scenario He had received ASA 325mg and NTG SL X3 per EMS. The ED gave him Retavase, PO Plavix, NTG infusion, Zofran, Fentanyl, and Heparin bolus and infusion. He was accepted at a PPCI and flown. Upon arrival to the tertiary care facility, his ECG showed some resolution of the ST elevation, but he still had persistent chest pain. He was taken semi-urgently to the Cath Lab. Receiving Hospital EKG 42

Case Scenario Once in the Cath Lab, it was discovered he had a Proximal LAD with 99% occlusion and the 1 st diagonal branch off the LAD was 80% occluded. He received 2 stents and had his occlusions reduced to 0% and 20%, respectively. Our gentleman was discharged home from the hospital 2 days later. What would you do? Case Study #1 Paramedics arrive to your ED with a 68 y/o male who c/o SSCP that awoke him from sleep 1 hour ago. The pain is still 7/10 despite 3 SL NTG and 6 mg of MS. Vital signs are: BP 88/56, HR 52, RR 28, SPO2 96% on 4 lpm NC. Skin signs are pale, cool, and clammy. He is anxious. The cardiac monitor show a SB w/o ectopy. Lungs are clear. He has 1 PIV of NS and has had 100cc PTA. What is your initial plan of care? 43

Case Study #1 His 12-lead EKG shows this: Case Study #1 This is what you see on the Right Heart 12- lead: Case Study #1 After 500cc of NS, vitals are: BP 100/62, HR 52 SB without ectopy, RR 24, SPO2 98% on 15 lpm by NRB. CP is still 7/10. What is your plan of care now, given the EKG? 44

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